The invention provides a cleansing composition, which comprises in addition to water, (a) from 10 to 30% by weight of one or more C6 to C16 acyl lactylates and (b) from 5 to 25% by weight of one or more co-surfactants, such as acyl taurates, isethionates, sarcosinates and sulphosuccinates. The cleansing compositions are primarily intended to be used as personal washing products, such as facial wash foams, bath foams and hair shampoos.

Patent
   5490955
Priority
Feb 27 1992
Filed
Mar 24 1995
Issued
Feb 13 1996
Expiry
Feb 25 2013
Assg.orig
Entity
Large
20
21
EXPIRED
1. A cleansing composition which comprises, in addition to water,
(a) from 15 to 35% by weight of one or more acyl lactylate(s) of the following structure (1) ##STR23## where R1 CO represents a C6 to C16 acyl radical; a is an integer from 1 to 3; M1 represents hydrogen or a counterion chosen from alkali metal, ammonium or a substituted ammonium group having one or more C1 to C3 alkyl or hydroxy alkyl group (s ); and
(b) from 5 to 25% by weight of one or more acylisethionates of the following structure (3)
R3 CO--OCH2 CH2 --SO3 M3 ( 3)
where R3 CO represents a C10 to C18 acyl group; and M3 is as M1 in structure (1); the composition having a foam height of more than 150 mm, as measured by the foam height Test, ASTM D 1173-53.
2. A composition according to claim 1, which has a foam height of more than 170 mm.
3. A composition according to claim 1, which has a foam height of more than 190 mm.
4. A composition according to claim 1, in which the acyl group R1 CO in structure (1) represents a C10 to C14 acyl radical.
5. A composition according to claim 1, in which the acylisethionate is present in an amount of 10 to 15% by weight.
6. A composition according to claim 1, which further comprises a quaternised ammonium hydroxy ethyl cellulose polymer in a foam modifying effective amount.
7. A composition according to claim 1, which further comprises from 5 to 25% by weight of one or more N-substituted betaines of the following structure (13) ##STR24## where Z13 represents (i) a C10 to C18 alkyl group; or
(ii) an R13 CO--NH--(CH2)3 group, where R13 CO represents a C10 to C18 acyl group.
8. Method of cleansing skin or hair using a composition according to claim 1 wherein said composition is applied to said skin or hair.

This is a continuation application of Ser. No. 08/023,186 filed Feb. 25, 1993, now abandoned.

The invention relates to cleansing compositions. In particular, the invention is concerned with very mild and high foaming cleansing compositions suitable for cleansing the skin and hair.

The most widely used anionic surfactants in cleansing compositions are alkyl sulphates, polyoxyethylene alkyl sulphates and alkyl benzene sulphonates. These compounds are known to have a good foaming and deterging power. Due to their harshness, however, they are not desirable as components for cleansing compositions topically applied to human skin and hair. Their damaging effect particularly where young, tender or damaged skin is involved, has been the subject of intense study for many years.

On the other hand milder surfactants often suffer from the draw-back that they do not provide high foam which is very important for the consumer. Therefore, there is a strong need for products which are not only very mild but also possess an excellent foaming power.

U.S. Pat. No. 3,728,447 (C. J. Patterson) discloses hair shampoo compositions containing fatty acid lactylates or glycolates. While the cleaning action of shampoos based on the fatty acid lactylates is satisfactory the foam is minimal. In order to achieve higher foaming action it is described to include harsh detergents such as sodium lauryl sulphate or triethanolamine lauryl sulphate. When the lactylates are used in conjunction with such a booster detergent the quantity of the lactylates present in the composition is reduced down to about 1 to 2% by weight.

EP-A-224 796 (Kao) describes a detergent composition comprising (a) a phosphate surfactant and (b) an acyl lactylate having an acyl group containing 12 to 18 carbons atoms. The detergent composition is said to have excellent foaming characteristics as well as excellent detergency and mildness to the skin and hair. It is taught that these characteristics are only achievable if the acyl lactylate is used in an amount of not more than 5% by weight and preferably not more than 3% by weight of the composition.

U.S. Pat. No. 4,761,279 (Eastman Kodak) describes shaving cream formulations comprising salts of acyl lactylates, saturated monoglycerides, propyleneglycol mono esters and humectants.

U.S. Pat. No. 4,946,832 (RITA Corporation) describes cosmetic base compositions comprising 1 to 15% by weight sucrose fatty acid ester, 3 to 45% by weight acyl lactylate or its alkali metal salts and solvent. The compositions promote wound healing and reduces skin dryness. Foaming properties of the compositions are not reported.

Applicants in their search for mild cleansing compositions, in particular for cleansing human skin or hair, with the added attribute that full lather is produced, have unexpectedly discovered that a narrow range of acyl lactylates in combination with specific co-surfactants provide the desired effects when used in particular amounts. The compositions so obtained are capable of producing a superior lather and accordingly have great consumer appeal. Also, the compositions are so mild that they can safely be used for cleansing the skin and the hair and other more delicate skin areas.

Accordingly, the invention provides a cleansing composition which comprises, in addition to water,

(a) from 10 to 35% by weight of one or more acyl lactylate(s) of the following structure (1) ##STR1## where R1 CO represents a C6 to C16 acyl radical; a is an integer from 1 to 3; M1 represents hydrogen or a counterion chosen from alkali metal, ammonium or a substituted ammonium group having one or more C1 to C3 alkyl or hydroxy alkyl group(s); and

(b) from 5 to 25% by weight of one or more co-surfactant(s) chosen from the following compounds (A) to (O):

(A) N-methyl-N-acyl taurates of the following structure (2) ##STR2## where R2 CO represents a C10 to C18 acyl group; and M2 is as M1 in structure (1);

(B) Acylisethionates of the following structure (3)

R3 CO--OCH2 CH2 --SO3 M3 (3)

where R3 CO represents a C10 to C18 acyl group; and M3 is as M1 in structure (1);

(C) Alkylesters of ω-sulphonated carboxylic acids of the following structure (4) ##STR3## where R4 represents a C10 to C18 alkyl group; M4 is as M1 in structure (1); and (b) is an integer from 1 to 3;

(D) Fatty acylamido polyoxyethylene sulphates of the following structure (5)

R5 CO--NH--(CH2 CH2 O)c --SO3 M5(5)

where R5 CO represents a C10 to C18 acyl group; M5 is as M1 in structure (1); and c is an integer from 1 to 10;

(E) Fatty acid polyglyceride sulphates of the following structure (6)

R6 CO--O--(CH2 --CHOH--CH2 O)d --SO3 M6(6)

where R6 CO represents a C10 to C18 acyl group; M6 is as M1 in structure (1); and d is an integer from 1 to 4;

(F) Mono substituted sulphosuccinates of the following structures (7a) or (7b) ##STR4## where Z7 is chosen from the following groups (i) to (iii): (i) R8 CO--NH--(CH2 CH2 O)e --, where Ra CO represents a C10 to C18 acyl group; and e is an integer from 1 to 10;

(ii) Rb --O--(CH2 CH2 O)f --, where Rb represents a C10 to C1 8 alkyl group; and f is an integer from 1 to 10;

(iii) Rc --O--, where Rc represents a C10 to C18 alkyl group; and

X7 and Y7 are independently from each other chosen from the counterions represented by M1 in structure (1);

(G) Mono substituted phosphates of the following structure (8) ##STR5## where R8 represents a C10 to C18 alkyl group; M8a and M8b are independently from each other chosen from the group of species represented by M1 in structure (1); and g is an integer from 0 to 3;

(H) Alkyl poly(ethylene glycol) acetates of the following structure (9) ##STR6## where R9 represents a C10 to C18 alkyl group; M9 is as M1 in structure (1); and h is an integer from 1 to 10;

(I) Salts of N-acyl α-amino acids of the following structure (10) ##STR7## where R10 CO represents a C10 to C18 acyl group; Z10 represents H or C1 to C2 alkyl; Y10 represents H, C1 to C3 alkyl or C1 to C3 alkyl substituted with a COOH group; and M10 is chosen from the counterions represented by M1 in structure (1);

(K) Alkyl polyglucosides of the following structure (11) ##STR8## where R11 represents a C10 to C14 alkyl group; and n is an integer from 1 to 3;

(L) Poly(oxyalkylene) fatty alkyl ether of the following structure (12)

R12 --O--(Z12 O)p H (12)

where R12 represents a C8 to C18 alkyl group; Z12 is a C2 or C3 alkylene group; and p is an integer from 1 to 10;

(M) N-substituted betaines of the following structure (13) ##STR9## where Z13 represents (i) a C10 to C18 alkyl group; or

(ii) a R13 CO--NH--(CH2)3 group, where R13 CO represents a C10 to C18 acyl group;

(N) Sultaines of the following structure (14) ##STR10## where Z14 represents a C10 to C18 alkyl group or a C10 to C18 acyl amido group;

(O) Alkyl amphocarboxylates of the following structure (15) ##STR11## where R15 CO represents a C10 to C18 acyl group; Z15 and Y15 are independently from each other chosen from H, CH2 CH2 OH or (CH2)r COO- ; r is 1 or 2; and M15 is as M1 in structure (1);

the composition having a foam height of more than 130 mm, as measured by the foam height test described herein.

The Acyl lactylate

The composition according to the invention comprises from 10 to 35% by weight of one or more acyl lactylate(s) of the following structure (1) ##STR12## where R1 CO represents a C6 to C16 acyl radical; a is an integer from 1 to 3; M1 represents hydrogen or a counterion chosen from alkali metal, ammonium or substituted ammonium group having one or more C1 to C3 alkyl or hydroxy alkyl group (s).

Examples of acyl lactylates having the above structure (1) include:

Sodium lauroyl monolactylate

Sodium myristoyl monolactylate

Sodium decanoyl monolactylate

Potassium dodecanoyl monolactylate

Potassium dodecanoyl dilactylaate

Sodium myristoyl dilactylate

Sodium lauroyl dilactylate

Lauroyl dilactylic acid

Palmitoyl dilactylic acid

Triethanolammonium dodecanoyl monolactylate

Ammonium decanoyl monolactylate, and

Triethanolammonium decanoyl monolactylate.

The preferred acyl group R1 CO is a C10 to C14 acyl group.

Preferred examples for M1 include sodium, potassium, ammonium and triethanolammonium.

The amount of the acyl lactylate present in the composition according to the invention is preferably from 15 to 30%, most preferred from 20 to 30% by weight of the composition.

The Co-surfactant

The composition according to the invention further comprises one or more co-surfactant(s) in an amount from 5 to 25% by weight of the composition. The co-surfactant is chosen from the compounds (A) to (O) described hereinafter.

The preferred amount of the co-surfactant present in the composition is from 10 to 25% by weight.

The co-surfactants useful in the present invention are not only very mild but also result in high foaming compositions when combined with the acyl lactylate in the specified amounts.

The following compounds are suitable as co-surfactant in the cleansing composition according to the invention.

(A) N-methyl-N-acyl taurates, having the following structure (2) ##STR13## where R2 CO represents a C10 to C18 acyl group; and M2 is as M1 in structure (1).

Preferred examples for taurates having the structure (2) include:

Sodium N-methyl-N-cocoyl taurate, e.g. available as Diapon K from Nippon Oil and Fats,

Sodium N-methyl-N-lauroyl taurate, e.g. available as Diapon LM from Nippon Oils and Fats,

Sodium N-methyl-N-myristoyl taurate, e.g. available as Nikkol MMT from Nikkol Chemicals.

(B) Acylisethionates, having the structure (3);

R3 CO--OCH2 CH2 --SO3 M3 (3)

R3 CO represents a C10 to C18 acyl group; and M3 is as M1 in structure (1).

The preferred example for an Acylisethionate having the structure (3) is sodium cocoyl isethionate, e.g. available as Fenopon AC 78 from Rhone Poulenc.

(C) Alkylesters of ω-sulphonated carboxylic acids, having the structure (4); ##STR14## where R4 represents a C10 to C18 alkyl group; M4 is as M1 in structure (1); and (b) is an integer from 1 to 3.

The preferred example for an Alkylester of a ω-sulphonated carboxylic acid having the structure (4) is sodium lauryl sulphoacetate, e.g. available as Lathanol LAL from Stepan or as Nikkol LSA and Nikkol Chemicals.

(D) Fatty acylamido polyoxyethylene sulphates, having the structure (5);

R5 CO--NH--(CH2 CH2 O)c --SO3 M5(5)

where R5 CO represents a C10 to C18 acyl group; M5 is as M1 in structure (1); and c is an integer from 1 to 10.

The preferred example for a sulphate having the structure (5) is sodium cocoyl amide EO-3 sulphate, e.g. available as Sunamide C-3 from Nippon Oils & Fats.

(E) Fatty acyl polyglyceride sulphates, having the structure (6);

R6 CO--O--(CH2 --CHOH--CH2 O)d --SO3 M6(6)

where R6 CO represents a C10 to C18 acyl group; M6 is as M1 in structure (1); and d is an integer from 1 to 4;

A preferred example for a fatty acyl poly(glyceride) sulphate having the structure (6) is sodium cocoyl monoglyceride sulphate, available from Jan Dekker International.

(F) Mono substituted sulphosuccinates, having the structures (7a) or (7b); ##STR15## where Z7 is chosen from the following groups (i) to (iii): (i) Ra CO--NH--(CH2 CH2 O)e --, where Ra CO represents a C10 to C18 acyl group; and e is an integer from 1 to 10;

(ii) Rb --O--(CH2 CH2 O)f --, where Rb represents a C10 to C18 alkyl group; and f is an integer from 1 to 10;

(iii) Rc --O--, where Rc represents a C10 to C18 alkyl group; and

X7 and Y7 are independently from each other chosen from the counterions represented by M1 in structure (1).

Preferred examples for mono substituted sulphosuccinates represented by the structures (7a) and (7b) include:

Disodium lauroyl amido (EO)-2 to 3 sulphosuccinate e.g. available as Beaulight A-5000 from Sanyo Chemicals,

a mixture of Disodium lauryl (PEG)-2 sulphosuccinate and Disodium myristyl (PEG)-2 sulphosuccinate, e.g. available as Beaulight ESS from Sanyo Chemicals,

Disodium lauryl (PEG)-2 to 3 sulphosuccinate, e.g. available as Rewopol SBFA 30 from Rewo, and

Disodium lauryl sulphosuccinate, e.g. available as Beaulight SSS from Sanyo Chemicals.

The short form (EO)-2 to 3 denotes that, as an average value, 2 to 3 oxyethylene groups are present per molecule sulphosuccinate. On the other hand, the short form (PEG)-2 to 3 stands for the presence of a polyethylene glycol group derived from, as an average value, 2 to 3 ethylene glycol molecules per molecule sulphosuccinate.

(G) Mono substituted phosphates, having the structure (8), ##STR16## where R8 represents a C10 to C18 alkyl group; M8a and M8b are independently from each other chosen from the group of species represented by M1 in structure (1); and g is an integer from 0 to 3.

Preferred examples for Mono substituted phosphates having the structure (8) include:

Monosodium monolauryl phosphate, e.g. available as Phosten HLP from Nikkol Chemicals,

Monosodium monolauryl (EO)-1 phosphate, e.g. available as Phosten HLP-1 from Nikkol Chemicals, and

Monosodium monolauryl (EO)-2 to 3 phosphate, e.g. available as Phosphanol ML 220 from Toho Chemicals.

(H) Alkyl poly(ethylene glycol) acetate, having the structure (9), ##STR17## where R9 represents a C10 to C18 alkyl group; M9 is as M1 in structure (1); and h is an integer from 1 to 10.

Preferred examples for Alkyl (PEG) acetates having the structure (9) include, Sodium Cocoyl PEG-10 acetate, e.g. available as Marlinat CM 105 from Huls, and Sodium tridecyl (PEG)-3 acetate, e.g. available as Beaulight ECA from Sanyo Chemicals.

(I) Salts of N-acyl α-amino acids, having the structure (10); ##STR18## where R10 CO represents a C10 to C18 acyl group; Z10 represents H or C1 to C2 alkyl; Y10 represents H, C1 to C3 alkyl or C1 to C3 alkyl substituted with a COOH group; and M10 is chosen from the counteriouns represented by M1 in structure (1).

Preferred examples for salts of N-acyl α-amino acids having the structure (10) include:

Sodium N-lauroyl glutamate, available as Amisoft, LS-11 from Ajinomoto Inc.,

Sodium N-cocoyl glutamate, e.g. available as Amisoft CS-11 from Ajinomoto Inc.,

Triethanolammonium N-cocoyl sarcosinate, e.g. available as Firet KT from Nippon Oil and Fats,

Sodium N-decanoyl sarcosinate,

Sodium N-lauroyl alaninate, e.g. available as Alaninate LN-30 from Nikkol Chemicals,

Sodium N-cocoyl alaninate,

Sodium N-cocoyl aspartate, and

Sodium N-lauroyl aspartate.

(K) Alkyl poly glucoside, having the structure (11); ##STR19## where R11 represents a C10 to C14 alkyl group; and n is an integer from 1 to 3.

Preferred examples for Alkyl poly glucosides having the structure (11) include;

Decyl poly glucoside (n=1.44), e.g. available as Oramix NS10 from Seppic, and

C9 -C11 Alkyl poly glucoside (n=1.4), e.g. available as APG 300 from Henkel.

(L) Poly(oxyalkylene) fatty alkyl ether, having the structure (12),

R12 --O--(Z12 O)p H (12)

where R12 represents a C8 to C18 alkyl group; Z12 is a C2 or C3 alkylene group; and p is an integer from 1 to 10.

Preferred examples for a poly(oxyalkylene)-fatty alkyl ether having the structure (12) are (PEG)-6 lauryl ether and (PEG)-6 myristyl ether. A mixture of (PEG)-6 C12 -C15 is available as Dobanol 91-6 from Shell Chemicals.

(M) N-substituted Betaines, having the structure (13); ##STR20## where Z13 represents (i) a C10 to C18 alkyl group; or

(ii) a R13 CO--NH--(CH2)3 group, where R13 CO represents a C10 to C18 acyl group.

Preferred examples for N-substituted Betaines having the structure (13) include:

Lauryl dimethyl betaine, e.g. available as Empigen BB from Albright & Wilson, and

cocoamidopropyl betaine, e.g. available as Tegobetaine L7F from Goldschmidt.

(N) Sultaines, having the structure (14); ##STR21## where Z14 represents a C10 to C18 alkyl group or a C10 to C18 acyl amido group.

A preferred example for a Sultaine having the structure (14) is Cocoamidopropyl hydroxysultaine, e.g. available as Cycloteric BET-CS from Alcolac.

(O) Alkylamphocarboxylates, having the structure (15); ##STR22## where R15 CO represents a C10 to C18 acyl group; Z15 and Y15 are independently from each other chosen from H, CH2 CH2 OH or (CH2)r COO- ; r is 1 or 2; and M15 is as M1 in structure (1).

Preferred examples for Alkylamphocarboxylates having the structure (15) include:

Cocoamphoglycinate e.g. available from GAF,

Wheatgerm amphodiglycinate,

Cocamphodipropionate, e.g. available as Mirataine C2MS from Rhone Poulenc,

Caprylamphodipropionate, e.g. available as Miranol S2MSF from Rhone Poulenc,

Cocoamphoacetate, e.g. available as Nissan Anon GLM-R from Nippon Oils & Fats.

Water

The cleansing composition according to the invention also comprises water. The water will normally be present in an amount of up to 85%, preferably from 10 to 85% by weight of the composition.

Optional Ingredients

The cleansing composition according to the invention can also comprise optional ingredients to modify the physical or chemical characteristics of the composition, e.g. product form, foaming properties, pH-value or shelf life.

Examples for ingredients which can be included in the compositions according to the invention are:

Emollients, such as:

[PEG]-20 Corn Glycerides,

[PEG]-60 Corn Glycerides,

[PEG]-20 Almond Glycerides,

[PEG]-60 Almond Glycerides,

[PEG]-12 Palm Kernel Glycerides,

[PEG]-45 Palm Kernel Glycerides,

[PEG]-20 Evening Primrose Glycerides,

[PEG]-60 Evening Primrose Glycerides,

Ethoxylated (EO)-20 methyl glucoside, also referred to as Methyl gluceth-20

Propoxylated (EO)-10 methyl glucoside.

A group of preferred emollients are poly (oxyalkylene) glycerides mono-substituted with a C10 to C18 alkyl group and having up to 20 C2 to C3 oxyalkylene moieties per molecule of the glyceride, as an average value.

Especially preferred emollients are Polyoxyalkylene methyl glucosides having, as an average value, up to 20 C2 -C3 oxyalkylene moieties per molecule glucoside. These emollients are very beneficial as they impart a soft feeling to the skin and support the ability of the skin to retain moisture. Examples for such Polyoxyalkylene methyl glucosides are available as Glucam E-20 and Glucam P10, respectively, from Amerchol.

Humectants, such as glycerine, sorbitol, sodium 2-pyrrolidone-5-carboxylate, soluble collagen, gelatine, ethoxylated (EO)-20 methyl glucoside, and propoxylated (EO)-10 methyl glucoside.

Preservatives, such as ethanol, benzoic acid, sodium benzoate, sorbic acid, alkali metal halides;

PH controlling agents, such as Sodium hydroxide, Citric acid, Triethanolamine, Potassium hydroxide, Amino Sorbitol. The pH controlling agents are preferably present in an amount sufficient to adjust the composition to a pH value in the range of 5.5 to 8.5.

Propellants, such as fluorochloro hydrocarbons, propane, butane, isobutane, dimethyl ether, carbon dioxide, nitrous oxide;

Foam modifying agents, such as cationic polymers, especially quaternised ammonium hydroxy ethyl cellulose polymers, e.g. available as polyquaternium-24 or polyquaternium-10. These polymers make the foam creamier and richer.

Further Optional Ingredients

The composition according to the invention can also contain other optional agents, that is ingredients other than the main ingredients already defined which are conventionally employed in cleansing compositions, such as thickeners.

The cleansing composition according to the invention is primarily intended as a personal washing product for cleansing the face. It can also be used for washing the hair as well as the whole body. The composition according to the invention is preferably used as facial cleanser, facial wash foam, hair shampoo, body shampoo, bath foam or shaving cream. Due to the high detergency provided by the composition it is also possible to use it in non-cosmetic applications, such as a household cleanser, carpet cleanser or detergent for tableware.

The following procedure is an example for the use of the cleansing composition according to the invention; a small quantity, for example from 1 to 5 ml, of the composition is either rubbed between the hands, together with water together to form a foam which is then used for washing or applied via a sponge to the area to be cleansed, or the foam is generated directly on that area. The foam is subsequently rinsed away with clean water.

The cleansing composition according to the invention can take the form of a liquid or gel, intended to be dispensed from a capped container such as a bottle, roll-on applicator or tube, or a pump-operated or propellant-driven aerosol dispenser. The composition can also take the form of a solid, such as a stick or a bar or tablet intended to be used for washing instead of a conventional soap bar.

Foaming Properties of the Composition

Although the composition according to the invention does not include harsh surfactants, as are found in conventional cleansing compositions, its foaming power is excellent. This is shown by the foam-heights measured by the Foam-Height Test described hereinafter.

Foam-Height Test

The test-method which has been used to assess the foaming power of the cleansing compositions according to the invention is the ASTM D 1173-53 test, also referred to as Ross-Miles test, and described in J. Ross and G. D. Miles, American Society for Testing Materials, 1953, pages 644-646. The test has been carried out at a temperature of 20°C by using an aqueous test solution of 0.3% by weight acyl lactylate and 0.1% by weight co-surfactant. This is a realistic concentration of the cleansing composition according to the invention when used by the consumer, e.g. when topically applied on the face or body together with water to generate the desired foam. The pH value of the test solution has been adjusted to a pH of 7.5 by addition of aqueous sodium hydroxide solution.

The following Table I shows the foam heights obtained by using various cleansing compositions according to the invention. In any case the acyl lactylate was a mixture of 70% by weight sodium lauroyl lactylate and 30% by weight myristoyl lactylate. This mixture is available under the trade name Pationic 138C from RITA Patterson. The foam height measured for this mixture without added co-surfactant is quoted as experiment (27).

TABLE I
______________________________________
Foam-
Co-surfactant height (mm)
______________________________________
(1) Sodium N-methyl-N-cocoyl taurate
193
(2) Sodium N-methyl-N-lauroyl taurate
198
(3) Sodium N-methyl-N-myristoyl taurate
193
(4) Triethanolammonium N-cocoyl sarcosinate
210
(5) Sodium N-cocoyl glutamate
165
(6) Sodium cocoyl isethionate
185
(7) Sodium mono lauryl phosphate
180
(8) Sodium mono lauryl [EO]-1 phosphate
160
(9) Sodium mono lauryl [EO]-2 to 3
190
phosphate
(10) Sodium cocoyl [PEG]-10 acetate
180
(11) Sodium tridecyl [PEG]-3 acetate
155
(12) Sodium N-lauroyl alaninate
172
(13) Sodium lauryl sulphoacetate
194
(14) Sodium cocoyl amido [EO]-3 sulphate
190
(15) Disodium lauroyl amido [EO]-2 to 3
148
sulphosuccinate
(16) Disodium lauryl sulphosuccinate
175
(17) Disodium lauryl [PEG]-2 to 3
170
sulphosuccinate
(18) Mixture of Disodium lauryl/myristyl
180
[PEG]-2 sulphosuccinate
(19) Sodium cocoyl mono glyceride sulphate
158
(20) Decyl polyglucoside (N* = 1.44)
170
(21) C9 --C11 Alkyl polyglucoside (n* = 1.4)
172
(22) [PEG]-6 C12 --C15 fatty alkyl ether
168
(23) N-lauryl dimethyl betaine
180
(24) Cocoamidopropyl betaine 170
(25) Cocoamphodipropionate 165
(26) Cocoamphoacetate 173
(27) -- 125
______________________________________
n* degree of polymerisation, cf. structure (11)

It can be seen from experiment (27) that all the co-surfactants used in experiments (1)-(26) enhance the foam height of the acyl lactylate mixture Pationic 138C to some degree. In particular, taurates having the structure (2), sarcosinates having the structure (10), sulphosuccinates , having the structures (7a) or (7b) and isethionates having the structure (3) are capable of increasing the foam height drastically.

The components of the composition and their amounts are chosen in such a manner that the cleansing composition according to the invention has a foam height of more than 130 mm, as measured by the foam height test carried out under the conditions described above.

Preferably the compositions according to the invention have a foam height of more than 150 mm, more preferred more than 170 mm and most preferred more than 190 mm.

The superiority of the compositions according to the invention as compared to conventional products is shown by the foam heights stated in the following Table II for facial wash foams based on conventional surfactant systems. Again the Ross-Miles test under the above defined conditions was carried out to assess the respective foam heights. The test solutions were aqueous solutions containing the conventional product at a concentration of 1.0% by weight. The percentages given below for the ingredients of the surfactant systems are based on the weight of the respective product.

TABLE II
______________________________________
Surfactant-System Foam Height (mm)
______________________________________
(1) 14% cocoyl isethionate
99
(2) 37% mixture of C18 /C16 /C14 /C12
76
potassium soaps
(3) 36% mixture of C14 /C12
52
triethanolammonium soaps
(4) 19% Fatty acyl glutamate,
70
2% Fatty acyl sarcosinate,
4% C14 /C12 potassium soap,
(5) 10% nonionic surfactant,
114
4% ether sulphate,
1.6% Fatty acyl sarcosinate
(6) 30% C18 /C14 /C12 potassium soaps
54
5% Sodium lauroyl glutamate
(7) 10% Sodium lauryl ethersulphate
128
4% Cocamidopropyl betaine
______________________________________

The above data clearly show that the compositions according to the invention give a much higher foam height than cleansing compositions based on conventional surfactant systems.

Although the cleansing compositions according to the invention comprise high amounts of acyl lactylate, namely from 10 to 30% by weight an excellent foaming power is achieved, as is shown by the data in Table I. This is clearly in contrast to the teaching of the prior art as disclosed in EP-A-224 796 (Kao) that only amounts of less than 5% by weight of acyl lactylate should be included in surfactant systems to obtain mild and high foaming cleansing compositions.

The data given in Table III below show the greater foaming power obtainable by compositions embodying the present invention compared to the prior art described in EP-A-224796. Examples (i) to (viii) in Table III contain the same lactylates in the same amounts as corresponding Examples 2 to 9 in Table 7-1 of EP-A-224796. In each of cases (i) to (viii) a 7:3 mixture of triethanolamine mono:di lauryl phosphate was present at a level of 15 wt %, triethanolamine was added to adjust the pH to 7.5 and demineralised water was used to 100 wt %. As shown in Table III in each case the lactylate content is less than 5 wt % and the foam height, as measured by the Ross-Miles test described above, is less than 130 mm.

TABLE III
______________________________________
Lactylate present Foam height (mm)
______________________________________
(i) 0.5 wt % stearoyl lactylate
100
(ii) 2.0 wt % stearoyl lactylate
100
(iii) 0.5 wt % iso-stearoyl lactylate
105
(iv) 2.0 wt % iso-stearoyl lactylate
100
(v) 0.5 wt % lauroyl lactylate
105
(vi) 2.0 wt % lauroyl lactylate
115
(vii) 0.5 wt % myristoyl lactylate
105
(viii)
2.0 wt % myristoyl lactylate
109
______________________________________

In contrast Table IV below gives the foaming power of compositions embodying the present invention. The foaming power was measured by the Ross Miles test described above. In each case the solutions were adjusted to pH 7.5 by addition of 20% aqueous solution of NaOH and were made up to 100% with demineralised water.

TABLE IV
______________________________________
Foam
Surfactant System Height (mm)
______________________________________
(ix) 17 wt % 1:1 Sodium C10 :C12 lactylate
135
2 wt % Sodium N-myristoyl-N-methyl
taurate
(x) 10 wt % 7:3 Sodium C12 :C14 lactylate
135
5 wt % Disodium lauryl/myristoyl
sulphosuccinate
(xi) 15 wt % 7:3 Sodium C12 :C14 lactylate
160
2 wt % triethanolamine mono:di
7:3 lauryl phosphate
(xii)
17 wt % 7:3 Sodium C12 :C14 lactylate
150
2 wt % Decyl polyglucoside
(xiii)
17 wt % 7:3 Sodium C12 :C14 lactylate
150
2 wt % Sodium cocoyl isethionate
______________________________________

As can be seen from Table IV each surfactant system embodying the present invention had a foam height above 130 mm.

The superiority of the cleansing compositions according to the invention to conventional compositions comprising less than 10% by weight of acyl lactylate is demonstrated by the data given in the following Table V.

The foam heights were again measured by the Ross-Miles Test conducted under the conditions as defined above.

All percentages given are based on the weight of the respective test solution. All test solutions were adjusted to a pH value of 7.5 by addition of aqueous NaOH solution.

TABLE V
______________________________________
Foam
Test Solutions Height (mm)
______________________________________
(A) 5% lauroyl dilactylic acid
112
5% Triethanolammonium laury sulphate
5% Coconut diethanolamide
to 100% demineralised water
(B) 7% lauroyl dilactylic acid
119
5% Triethanolammonium laury sulphate
3% Coconut diethanolamide
to 100% demineralised water
(C) 9% lauroyl dilactylic acid
116
1% Triethanolammonium laury sulphate
1% Coconut diethanolamide
to 100% demineralised water
(D) 9% lauroyl dilactylic acid
104
3% Triethanolammonium laury sulphate
1% Coconut diethanolamide
to 100% demineralised water
(E) 10% Sodium lauroyl/myristoyl lactylate
141
(Pationic 138 C)
4% Sodium cocoyl isethionate
1% Cocoampho carboxy glycinate
to 100% demineralised water
(F) 12% Sodium lauroyl/myristoyl lactylate
136
(Pationic 138 C)
1.5% Sodium N-lauroyl sarcosinate
1.5% Sodium N-methyl-N-cocoyl taurate
to 100% demineralised water
(G) 15% Sodium lauroyl/myristoyl lactylate
136
(Pationic 138 C)
2% Sodium laurylamide [EO]-3 sulphate
to 100% demineralised water
______________________________________

The above data show that, although the compositions according to the invention (E) to (G) are used in amounts of 10% by weight or more, they foam much better than the conventional compositions (A) to (D).

The following examples further illustrate the invention by giving conventionally prepared formulations for different types of cleansing compositions.

______________________________________
Example 1 - Facial Cleanser
wt %
______________________________________
Potassium dodecanoyl monolactylate
15.00
Potassium dodecanoyl dilactylate
15.00
Disodium lauryl sulphosuccinate
7.00
Glycerol (Humectant) 5.00
Sodium chloride (Thickener)
4.20
Methyl gluceth-20 (Humectant/Emollient)
3.00
Polyquaternium 10 (Foam modifier)
0.40
Ethyleneglycol monostearate (Thickener)
0.40
Preservative 0.30
Fragrance 0.30
Citric acid to pH 7.0-7.5
Distilled water to 100.00
Foam height = 153 mm
______________________________________
______________________________________
Example 2 - Mild Facial Cleanser
wt %
______________________________________
Sodium myristoyl dilactylate
20.00
Sorbitol (Humectant) 9.00
Sodium cocoyl isethionate 7.00
Cocoamidopropyl hydroxysulphobetaine
4.00
Polyoxyethylene [EO]-20 sorbitan monolaurate
3.00
(Thickener)
Hydroxypropyl methylcellulose (Thickener)
0.20
Preservative 0.20
Fragrance 0.10
Citric acid to pH 6.0-6.5
Distilled water to 100.00
Foam height = 162 mm
______________________________________
______________________________________
Example 3 - Facial Cleanser for Dry Skin
wt %
______________________________________
Sodium lauroyl dilactylate
25.00
Sodium monolauryl phosphate
10.00
Propylene glycol 10.00
Polyethyleneglycol (PEG)-150 distearate
5.00
Preservative 0.25
Fragrance 0.20
Citric acid to pH 6.5-7.0
Distilled water to 100.00
Foam height = 139 mm
______________________________________
______________________________________
Example 4 -
Mild Facial Cleanser for Sensitive Skin
wt %
______________________________________
Lauroyl dilactylic acid 20.0
Sodium N-methyl-N-myristoyl taurate
6.00
Cocoamphoacetate 3.50
Glycerol (Humectant) 9.00
Diglycerol (Humectant) 1.00
PEG-20 almond glycerides (Emollient)
5.00
Polyquaternium 24 (Thickener, Foam Modifier)
0.40
Sodium Hydroxide (aq. soln.)
to pH 6.0-6.5
Distilled water to 100.00
Foam height = 150 mm
______________________________________
______________________________________
Example 5 - Liquid Hand Soap
wt %
______________________________________
Lauroyl dilactylic acid 7.50
Palmitoyl dilactylic acid 7.50
Triethanolammonium N-lauroyl glutamate
9.00
Cocoamidopropyl betaine 4.00
Propyleneglycol hydroxy isostearate (Thickener)
1.00
Trisodium citrate (Thickener)
7.00
Preservative 0.26
Fragrance 0.15
Triethanolamine to pH 7.0-7.3
Distilled water to 100.00
Foam height = 144 mm
______________________________________
______________________________________
Example 6 -
Anti-Acne Facial Cleansing Scrub Gel
wt %
______________________________________
Sodium decanoyl monolactylate
18.00
Sodium N-cocoyl sarcosinate
6.00
Benzoyl peroxide (70% aq. soln.)
14.30
Polyoxyethylene (PEG)-20 cetyl ether
10.00
(Thickener, Emulsifier)
Magnesium aluminium silicate (Thickener)
1.00
Disodium ethylenediamine tetraacetate
0.20
(Chelating Agent)
Sodium Hydroxide to pH 7.0-7.5
Distilled water to 100.00
Foam height = 135 mm
______________________________________
______________________________________
Example 7 - Hair Shampoo wt %
______________________________________
Triethanolammonium dodecanoyl monolactylate
21.00
Sodium lauryl (PEG)-10 acetate
4.00
Cocoamphodipropionate 3.00
Propylene glycol (Humectant)
2.50
Sodium chloride (Thickener)
1.20
Preservative 0.20
Fragrance 0.20
Citric acid to pH 6.0-6.5
Distilled water to 100.00
Foam height = 158 mm
______________________________________
______________________________________
Example 8 - Mild Hair Shampoo
wt %
______________________________________
Potassium myristoyl dilactylate
15.00
Lauryl ethoxylated (EO)-2.5 phosphoric acid
8.00
Sodium pyrrolidone carboxylate (50% aq. soln.)
1.00
(Humectant)
Sodium chloride (Thickener)
3.00
Fragrance 0.24
Preservative 0.10
Potassium hydroxide (aq. soln.)
to pH 6.0-6.5
Distilled water to 100.00
Foam height = 141 mm
______________________________________
______________________________________
Example 9 - Conditioning Shampoo
wt %
______________________________________
Potassium lauroyl monolactylate
11.00
Sodium lauroylamide polyoxyethylene (EO)-3
4.50
sulphate
Lauryldimethyl betaine 4.00
Potassium chloride (Thickener)
2.50
Dimethicone copolyol (Conditioning agent)
0.50
Preservative 0.17
Fragrance 0.11
Dye 0.02
Citric acid to pH 6.5-7.0
Distilled water to 100.00
Foam height = 170 mm
______________________________________
______________________________________
Example 10 - Antidandruff Shampoo
wt %
______________________________________
Ammonium decanoyl monolactylate
14.00
Ammonium decanoyl dilactylate
4.00
Ammonium lauryl sulphoacetate
5.00
Zinc Pyrithione (48% aq. soln.) (Anti-fungal
2.10
agent)
Hydroxypropyl methylcellulose
1.25
Magnesium aluminium silicate (Thickener)
1.00
Preservative 0.36
Fragrance 0.20
Dye 0.03
Citric acid to pH 7.0-7.3
Distilled water to 100.00
Foam height = 150 mm
______________________________________
______________________________________
Example 11 - Body Shampoo
wt %
______________________________________
Dodecanoyl dilactylic acid
13.00
Sodium N-cocoyl alaninate
4.00
Lauroamphoglycinaate 4.00
(PEG)-80 sorbitan laurate (Thickener)
3.30
Disodium ethylenediamine tetraacetate
0.20
Preservative 0.10
Fragrance 0.05
Dye 0.01
Citric acid to pH 7.0-7.5
Distilled water to 100.00
Foam height = 164 mm
______________________________________
______________________________________
Example 12 - Mild Body Shampoo
wt %
______________________________________
Triethanolammonium lauroyl monolactylate
7.50
Triethanolammonium myristoyl monolactylate
7.50
Disodium lauryl (PEG)-2.5 sulphosuccinate
10.00
Cocoamidoproyl betaine 5.00
Glycerol 5.00
Polyoxyethylene (PEG)-45 monostearate
2.00
(Thickener)
Preservative 0.35
Fragrance 0.35
Citric acid to pH 7.0-7.5
Distilled water to 100.00
Foam height = 165 mm
______________________________________
______________________________________
Example 13 - Liquid Body Shampoo
wt %
______________________________________
Potassium decanoyl monolactylate
10.00
Potassium decanoyl dilactylate
10.00
Decyl polyglucoside (n = 1.44)
5.00
Glycerol 5.00
Trisodium citrate dehydrate (Thickener)
1.50
Sodium carboxymethyl cellulose (Thickener)
1.00
Citric acid to pH 7.0-7.5
Distilled water to 100.00
Foam height = 138 mm
______________________________________
______________________________________
Example 14 - Aerosol Body Shampoo
wt %
______________________________________
Sodium decanoyl monolactylate
10.00
Sodium decanoyl dilactylate
10.00
Decyl polyglucoside (n = 1.44)
5.50
Glycerol 2.00
Trisodium citrate dihydrate
1.50
Sodium carboxymethyl cellulose
1.00
Preservative 0.35
Fragrance 0.35
Citric acid to pH 7.0-7.5
Distilled water to 100.00
Foam height = 140 mm
______________________________________

95% by weight of the solution obtained by mixing the above ingredients was combined with 5% by weight propellant and then sealed into a container.

______________________________________
Example 15 - Bath Foam Concentrate
wt %
______________________________________
Lauroyl monolactylic acid 15.00
Lauroyl dilactylic acid 10.00
Cocoamphopropionate 5.00
Sorbitol 9.00
Sodium chloride 6.00
Sodium carboxymethyl cellulose (Thickener)
1.00
Preservative 0.30
Fragrance 0.60
Chamomile distillate (Anti-inflammatory agent)
1.00
Aminosorbitol to pH 7.0-7.5
Distilled water to 100.00
Foam height = 165 mm
______________________________________
______________________________________
Example 16 - Mild Bath Foam
wt %
______________________________________
Sodium myristoyl monolactylate
18.00
Sodium myristoyl dilactylate
6.00
Sodium lauroyl monoglyceride sulphate
5.00
Cocoamidopropyl hydroxysulphobetaine
4.00
Preservative 0.20
Fragrance 1.00
Citric acid to pH 7.2-7.7
Distilled water to 100.00
Foam height = 149 mm
______________________________________
______________________________________
Example 17 - Conditioning Bubble Bath
wt %
______________________________________
Triethanolammonium decanoyl monolactylate
20.00
Cocoamphodiacetate 5.00
Polyoxyethylene (PEG)-20 cetyl ether
4.00
Polyoxyethylene (PEG)-50 stearyl ether
4.00
Lauryl methyl gluceth-10 hydroxypropyl
0.50
diammonium chloride (Conditioner)
Polyquaternium 24 (Thickener)
0.40
Citric acid to pH 7.0-7.5
Distilled water to 100.00
Foam height = 151 mm
______________________________________
______________________________________
Example 18 - Cleansing Bar
wt %
______________________________________
Sodium lauroyl dilactylate
20.00
Sodium myristoyl dilactylate
15.00
Sodium N-cocoyl glutamate
15.00
Sodium N-stearoyl aspartate
10.00
Glycerol 8.00
Diglycerol 8.00
Preservative 0.30
Fragrance 0.60
Pigment 0.10
Distilled water to 100.00%
Foam height = 175 mm
______________________________________
______________________________________
Example 19 - Facial Wash Foam
% w/w
______________________________________
Sodium lauroyl lactylate 14.00
Sodium myristoyl lactylate
6.00
Sodium lauryl ethoxy phosphate
6.00
Disodium lauroyl amido ethoxy sulphosuccinate
2.00
Disodium wheatgerm amido PEG-2
2.00
sulphosuccinate
Polyquaternium-24 0.40
Glycerol (humectant) 10.00
(PEG)-12 palm kernel glycerides (emollient)
5.00
Sodium hydroxide solution to pH 6.8-7.0
Distilled water to 100.00%
Foam height = 190 mm
______________________________________
______________________________________
Example 20 - Facial Wash Foam
% w/w
______________________________________
Sodium lauroyl lactylate
14.00
Sodium myristoyl lactylate
6.00
Sodium cocoyl isethionate
6.00
Wheatgerm amphodiacetate
2.00
Cocoamphocarboxy glycinate
2.00
Polyquaternium-24 0.40
Glycerol (humectant) 10.00
(PEG)-40 almond glycerides (emollient)
5.00
Sodium hydroxide solution
to pH 6.8-7.0
Distilled water to 100.00%
Foam height = 180 mm
______________________________________
______________________________________
Example 21 - Facial wash foam
wt %
______________________________________
Sodium lauroyl lactylate 14.00
Sodium myristoyl lactylate
6.00
Sodium cocoyl isethionate
6.75
Monolauryl phosphoric acid
2.40
Dilauryl phosphoric acid 0.60
Triethanolammonium N-cocoyl sarcosinate
1.00
Glycerol 10.00
Polyquaternium 10 0.40
Sodium hydroxide solution
to pH 6.8-7.0
Distilled water to 100.00%
Foam height = 185 mm
______________________________________
______________________________________
Example 22 - Facial wash foam
wt %
______________________________________
Sodium lauroyl lactylate
14.00
Sodium myristoyl lactylate
6.00
Sodium cocoyl isethionate
6.00
Sodium N-methyl-N-cocoyl taurate
3.00
Sodium N-cocoyl sarcosinate
1.00
Glycerol 10.00
Polyquaternium 10 0.40
Sodium hydroxide solution
to pH 6.8-7.0
Distilled water to 100.00%
Foam Height - 190 mm
______________________________________

Carter, Peter, Hagan, Desmond B.

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